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Reference
A Near‐Infrared‐II Emissive Chromium(III) Complex
SINHA, Narayan, et al.
Abstract
The combination of π-donating amido with π-accepting pyridine coordination units in a
tridentate chelate ligand causes a strong nephelauxetic effect in a homoleptic CrIII complex,
which shifts its luminescence to the NIR-II spectral range. Previously explored CrIII
polypyridine complexes typically emit between 727 and 778 nm (in the red to NIR-I spectral
region), and ligand design strategies have so far concentrated on optimizing the ligand field
strength. The present work takes a fundamentally different approach and focusses on
increasing metal–ligand bond covalence to shift the ruby-like 2E emission of CrIII to 1067 nm
at 77 K.
SINHA, Narayan, et al. A Near‐Infrared‐II Emissive Chromium(III) Complex. Angewandte
Chemie (International Edition), 2021, vol. 60, no. 44, p. 23722-23728
DOI : 10.1002/anie.202106398
PMID : 34125469
Available at:
http://archive-ouverte.unige.ch/unige:156643
Disclaimer: layout of this document may differ from the published version.
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Publication: Angew. Chem. Int. Ed. 2021, 60, 23722-23728. DOI: 10.1002/anie.202106398
A Near-Infrared-II Emissive Chromium(III) Complex
Narayan Sinha,[a] Juan-Ramón Jiménez,[b] Björn Pfund,[a] Alessandro Prescimone,[c] Claude Piguet,[b]* and Oliver S.
Wenger[a]*
[a] Department of Chemistry, University of Basel, St. Johanns-Ring 19, 4056 Basel, Switzerland [b] Department of Inorganic and Analytical Chemistry, University of Geneva, 30 quai E. Ansermet, 1211 Geneva 4,
Switzerland [c] Department of Chemistry, University of Basel, BPR 1096, Mattenstrasse 24a, 4058 Basel, Switzerland
E-Mail addresses: claude.piguet@unige.ch; oliver.wenger@unibas.ch
Abstract
The combination of -donating amido with -accepting pyridine coordination units in a tridentate chelate ligand
causes a strong nephelauxetic effect in a homoleptic CrIII complex, which shifts its luminescence to the NIR-II spectral
range. Previously explored CrIII polypyridine complexes typically emit between 727 and 778 nm (in the red to NIR-I
spectral region), and ligand design strategies have so far concentrated on optimizing the ligand field strength. The
present work takes a fundamentally different approach and focusses on increasing metal-ligand bond covalence to
shift the ruby-like 2E emission of CrIII to 1067 nm at 77 K.
2
1. Introduction
Chromium(III) complexes played a central role in the development of coordination chemistry, and nowadays serve as
textbook examples of substitution-inert compounds with rich optical spectroscopic and magnetic properties.[1] Many
Cr3+ containing materials show photo-luminescence in the solid state,[2] and carefully designed molecular complexes
of CrIII emit in solution at room temperature. However, under these latter conditions the luminescence quantum yields
() of classical polypyridine complexes such as those in Fig. 1a-c are typically on the order of 0.1% or lower.[3]
Fig. 1. Molecular structures of (a) [Cr(bpy)3]3+ (bpy = 2,2’-bipyridine),[3b, 4] (b) [Cr(phen)3]3+ (phen = 1,10-
phenanthroline),[3b, 4] (c) [Cr(tpy)2]3+ (tpy = 2,2’:6’,2’’-terpyridine),[3b, 4] (d) [Cr(ddpd)2]3+ (ddpd = N,N’-dimethyl-
N,N’-dipyridine-2-yl-2,6-diamine),[5] and (e) [Cr(dqp)2]3+ (dqp = 2,6-di(quinoline-8-yl)pyridine)[6] along with their
luminescence quantum yields () in solution at room temperature and wavelengths of emission band maxima (em). (f)
Molecular structure of the new [Cr(dpc)2]+ complex reported herein (dpc = 3,6-di-tert-butyl-1,8-di(pyridine-2-yl)-
carbazolato) and its emission peak wavelength.
For the recently disclosed [Cr(ddpd)2]3+ complex (Fig. 1d),[5, 7] -values up to 30% were achievable in solution,[8] and
this represented a quantum leap for the photophysics of molecular CrIII compounds. The ability of ddpd to chelate CrIII
with significantly larger bite angles than the ligands in Fig. 1a-c is a key factor contributing to the favorable
luminescence behavior of [Cr(ddpd)2]3+, and a similar concept was later exploited with the tridentate dqp ligand (Fig.
1e).[6, 9] The nearly ideal octahedral coordination of CrIII by ddpd and dqp implies strong spatial overlaps between the
spectroscopically relevant metal 3d- and ligand-orbitals, resulting in a strong ligand field created by the -acceptor
units pyridine and quinoline. As the coordination environments of [Cr(ddpd)2]3+ and [Cr(dqp)2]3+ deviate only
relatively little from Oh symmetry, undesirable splittings of degenerate excited states by symmetry lowering (such as
the case for example in the trigonally distorted [Cr(phen)3]3+ complex) can be kept minimal. These combined effects
of high symmetry and strong ligand field are helpful, because they increase the energy gap between the emissive 2E
and the higher-lying 4T2 state (Fig. 2a), thereby diminishing the thermal population of the latter (via reverse
intersystem crossing) and minimizing nonradiative relaxation from the strongly distorted 4T2 excited state. The
3
enhancement of ligand field strength (captured by an increase of the parameter 10 Dq) predominantly acts on the 4T2
energy, but affects the energy of the 2E spin-flip transition much less (Fig. 2b), and consequently the emission peak
wavelengths (em) of the CrIII complexes in Fig. 1a-e are relatively similar (727 – 778 nm). In other words, the strategy
pursued with the complexes in Fig. 1d/e (and its congeners)[5, 7-8, 10] is highly successful for the optimization of
luminescence quantum yields, but it is not well suited for emission color tuning.
Fig. 2. (a) Tanabe-Sugano diagram for the d3 valence electron configuration in Oh symmetry. Single configurational
coordinate diagrams illustrating (b) the influence of an increase in ligand field parameter (10 Dq) on the 2E, 2T1, and 4T2 energies and (c) the influence of an increase in metal-ligand bond covalence (decrease of Racah B parameter) on
the respective energies.
The energy of the 2E 4A2 spin-flip transition of CrIII is more susceptible to electron-electron repulsion than ligand
field strength (Fig. 2c). The mutual repulsion between d-electrons is quantified by the Racah B parameter, which
adopts a value of 918 cm-1 for the free Cr3+ ion in the gas phase.[11] In coordination environments, the formation of
metal-ligand bonds with covalent character leads to the nephelauxetic effect, meaning that d-electrons are spatially
more distributed and less confined to the metal core.[12] Consequently, their mutual repulsion diminishes, manifesting
in B-values on the order of 650 – 810 cm-1 for polypyridine complexes of CrIII. We reasoned that if metal-ligand bond
covalence was further increased, the 2E emission wavelength could possibly be shifted into the NIR-II region beyond
1000 nm. To the best of our knowledge, this has not been achievable yet with molecular CrIII complexes.[13]
NIR emitters have applications in light-emitting devices,[14] fiber-optic telecommunications,[15] anti-counterfeit inks,[16]
oxygen sensing,[5, 10] bio-sensing and bio-imaging,[17] as well as in night-vision readable displays.[18] Many of the
respective luminophores are based on lanthanide complexes[17] or coordination compounds with second- or third-row
transition metal elements,[19] whilst others are made from organic dyes or a combination of organic chromophores with
precious metal complexes.[20] NIR-II luminescence is particularly advantageous for in vivo imaging, for example to
locate malignant tissue due to its deep penetration, high signal to background ratio, and reduced interfering signals.[21]
The recent surge of interest in photoactive complexes made from Earth-abundant metals resulted in several
compounds emitting in the NIR-I region between 700 and 950 nm,[22] but NIR-II emitters are extremely scarce among
base metal complexes so far.[23] Obvious economic advantages can result from the replacement of precious and rare
4
metals by more abundant and cheaper alternatives, but furthermore the question how NIR-II emission can become
competitive with undesired excited-state relaxation processes in first-row transition metal complexes is of
considerable fundamental interest.[24]
Inspired by recent advances in iron(II) photophysics where the change from classical polypyridine ligands to chelates
with amido donors led to a drastically altered electronic structure,[25] we identified the tridentate dpc ligand (Fig. 1f) as
a promising candidate for CrIII complexes with red-shifted 2E luminescence. In the earlier FeII work,[26] so-called
“HOMO inversion” was in key focus,[27] whilst here the conceptually much different aspect of increased metal-ligand
bond covalence is of central interest. Comprised of a central -donating amido donor flanked by two -donating and
-accepting pyridine units, this chelate can be expected to coordinate CrIII in nearly optimal octahedral fashion,[25, 28]
hence the design of this ligand takes some of the lessons learned from the coordination bite-angle optimized
compounds in Fig. 1d/e into account. The key difference to the previously investigated complexes is the presence of
an anionic coordination unit, which strongly affects the electron density at the metal. -donor ligands commonly
weaken the ligand field due to energetic destabilization of the metal-based t2g-like orbitals,[29] which is in clear contrast
to the design principle of maximizing 10 Dq pursued in recent studies (Fig. 1d/e). We speculated that the dpc ligand
would enable increased overall metal-ligand bond covalence by offering a coordination environment in which -
electron density is shifted multi-directionally from amido-donors to CrIII and from CrIII to pyridine-acceptors. This
seems indeed to be the case, and our investigation points to a substantially lowered Racah B parameter, which gives
rise to the first NIR-II emissive CrIII complex.
2. Results and discussion
2.1 Synthesis, structure and electrochemistry
The tridentate ligand precursor, 3,6-di-tert-butyl-1,8-di(pyridine-2-yl)-carbazole (H-dpc), was synthesized following a
known procedure.[30] This compound was deprotonated with lithium diisopropylamide (LDA), and subsequent
addition of CrCl2 (99.99% purity) and halide exchange with potassium hexafluorophosphate under air resulted in the
formation of [Cr(dpc)2](PF6) as a dark red solid in 41% yield (Scheme 1). The new complex is stable under both acidic
and basic conditions (Fig. S4/S5).
Scheme 1. Synthesis of the new chromium(III) complex, [Cr(dpc)2](PF6).
5
Red colored single crystals of [Cr(dpc)2](PF6)2.5(C2H4Cl2) for an X-ray diffraction study were obtained by slow
vapor diffusion of n-hexane into a saturated solution of [Cr(dpc)2](PF6) in dichloroethane at 4 C. The structure
analysis revealed the expected mononuclear chromium(III) complex cation bearing two dpc ligands, which is shown
in Fig. 3. The complex cation features close to octahedral geometry for the six bound nitrogen atoms around the
chromium(III) center. The N(amido)CrN(amido) angle is 173.69(8), and the N(pyridine)CrN(pyridine) angles
are 173.16(7) and 173.66(7). These bond angles are very similar to those reported for [Cr(ddpd)2]3+.[5-6] The
CrN(amido) bond lengths (1.962(3) and 1.969(2) Å) are shorter than the CrN(pyridine) bonds (2.109(3)-
2.133(2)Å), which is compatible with the more covalent nature of the CrN(amido) bonds. A recent study of lithium
amides revealed significant covalent LiN bonding character, and comparatively short bond distances.[31] The two-
pyridine rings of a given dpc ligand are tilted from the plane of the central carbazole ring in such a way that the
tridentate ligand adopts a helical twist compatible with P and M chirality according to Cahn-Ingold-Prelog notation.[32]
As previously reported for [Cr(dqp)2]3+ 7 and [Cr(ddpd)2]3+,[33] the homochiral PP and MM pairs are more stable than
the heterochiral PM assembly in the chromium(III) complex, which therefore exists as a pair of PP-[Cr(dpc)2]+/MM-
[Cr(dpc)2]+ enantiomers in the crystal structure.
Fig. 3. Molecular structure of [Cr(dpc)2]+ in [Cr(dpc)2](PF6)2.5(C2H4Cl2) (H atoms, the counter ion and solvent
molecules are omitted for clarity, 50% probability ellipsoids). Selected bond angles () and bond distances (Å):
N2Cr1N5, 173.69(8); N1Cr1N3, 173.66(7); N4Cr1N6, 173.16(7); Cr1N2, 1.969(2); Cr1N5, 1.962(3);
Cr1N1, 2.133(2); Cr1N3, 2.115(3); Cr1N4, 2.109(3); Cr1N6, 2.133(2). CCDC 2082071
([Cr(dpc)2](PF6)2.5(C2H4Cl2)) contains the supplementary crystallographic data for this paper. These data can be
obtained free of charge from the Cambridge Crystallographic Data Centre.
The uncommon electronic structure of [Cr(dpc)2]+ readily manifests in cyclic voltammetry (Fig. 4a), where the first
reduction event is observable at -1.51 V vs Fc+/0 (-0.88 V vs NHE),[34] cathodically shifted by ca. 1.0 V relative to
[Cr(tpy)2]3+ and at ca. 0.4 V more negative potential than in [Cr(ddpd)2]3+.[5] The electron-poor pyridine ligands of
fused-five-membered tpy chelates in [Cr(tpy)2]3+ lead to a situation in which the first reduction process is ligand-
centered, occurring at +0.1 V vs NHE to give [CrIII(tpy.-)(tpy)]2+ with no trace of CrII.[35] On the other hand,
6
[Cr(ddpd)2]3+ with its fused six-membered electron-rich ddpd chelates exhibits metal-centered reduction at -0.48 V vs
NHE to give the spin-crossover compound [CrII(ddpd)2]2 +. The electron-rich character of our anionic dpc ligand,
combined with its six-membered chelate rings suggest an analogous metal-centered reduction to give [CrII(dpc)2]0, but
cathodically shifted with respect to [Cr(ddpd)2]3+ due to the high electron density at the metal center. The latter
characteristics furthermore facilitate the observation of a CrIV/III redox couple at 0.46 V vs Fc+/0 (-0.17 V vs NHE),
which does not seem to be detectable for the other complexes in Fig. 1. An additional wave at 0.78 V vs Fc+/0 in Fig.
4a is attributable to ligand oxidation, because a similar (though less reversible) wave (due to possible deprotonation) is
observed for the ligand precursor H-dpc (Fig. S6). See SI page S9 for a further discussion regarding the assignment of
the individual redox waves.
Fig. 4. (a) Cyclic voltammogram of 1 mM [Cr(dpc)2](PF6) in acetonitrile with 0.1 M (nBu4)(PF6) as supporting
electrolyte, recorded at a scan rate of 100 mV/s. (The Fc+/0 potential corresponds to 0.63 V vs NHE).[34] (b) UV-Vis
absorption spectrum of [Cr(dpc)2](PF6) in acetonitrile at 20 °C (black trace). The red trace shows the long-wavelength
part of this spectrum on a magnified -scale (right y-axis, recorded on a more concentrated solution, see inset). The
vertical black and red bars mark the energies of DFT-calculated vertical transitions, the heights of these bars reflect
relative oscillator strengths. The heights of the vertical red bars were multiplied by a factor of 10 relative to the
vertical black bars. (c) Luminescence spectrum of [Cr(dpc)2](PF6) in acetonitrile at 77 K, obtained after excitation at
450 nm.
2.2 UV-Vis absorption spectroscopy
The UV-Vis absorption spectrum of [Cr(dpc)2]+ in acetonitrile (Fig. 4b) exhibits ligand-centered -* absorption
bands between 220 and 330 nm with molar extinction coefficients () exceeding 30000 M-1 cm-1. The spectral range
between 330 and 450 nm is dominated by (spin-allowed) ligand-to-metal charge transfer (LMCT) absorptions
according to time-dependent DFT calculations (Tables S2-S3), along with some metal-to-ligand charge transfer
(MLCT) and (weaker) metal-centered (MC) absorption features. Given the anionic nature of the amido donor group,
the observation of 4LMCT absorptions is unsurprising, and based on the electrochemical data in Fig. 4a one would
expect some of them to fall into the visible range near 2.4 eV. At 500 nm there is a distinct absorption band ( = 4660
M-1 cm-1) which, according to the TD-DFT calculations, is attributable to an intraligand charge transfer (ILCT)
between carbazole and pyridine units. The presence of all these comparatively intense charge transfer (CT) absorption
bands makes the observation of the parity-forbidden MC absorptions difficult. The absorption band at 521 nm ( =
3000 M-1 cm-1) contains significant 4A2 4T2 character according to the TD-DFT calculations. For comparison, in the
7
[Cr(ddpd)2]3+ and [Cr(dqp)2]3+ complexes the 4T2 absorption maximum appears at 434 and 401 nm, respectively.[5-6] A
red-shift of the 4A2 4T2 absorption band in [Cr(dpc)2]+ is expected, as the amido -donor unit of dpc destabilizes the
t2g-like metal orbitals and thereby weakens the ligand field compared to the pyridine and quinoline -acceptor units of
ddpd and dqp.
Aiming to detect the spin-forbidden transitions from the 4A2 ground state to the 2E and 2T1 excited states, an
absorption spectrum of a more concentrated solution of [Cr(dpc)2](PF6) in acetonitrile was recorded (red trace in Fig.
4b), but instead of the anticipated rather narrow spectral features, two comparatively broad bands were observable.
The first of these two bands peaks at 690 nm with = 84 M-1 cm-1 and corresponds to a spin-forbidden 2LMCT
according to TD-DFT. The second band around 970 nm is yet an order of magnitude weaker ( = 6 M-1 cm-1) and will
be discussed below alongside luminescence data.
2.3 Photoluminescence
Following excitation of [Cr(dpc)2](PF6) at 450 nm in acetonitrile at 77 K, the luminescence spectrum in Fig. 4c was
recorded. The emission peak is at 1067 nm, flanked by a tail extending to 1350 nm and a weaker shoulder at shorter
wavelengths. The excitation spectrum of the emission at 1067 nm matches the absorption spectrum between 350 and
550 nm well (Fig. S12). Pulsed excitation at 350 nm reveals a bi-exponential decay of the luminescence signal at 1067
nm (Fig. S11) with lifetimes () of 1.4 s (88%) and 6.3 s (12%). Three facts seem particularly noteworthy
concerning this emission: (i) its long wavelength compared to the other complexes from Fig. 1 for which 2E 4A2
luminescence typically peaked between 727 and 778 nm; (ii) its comparatively broad spectral bandwidth; (iii) its
relatively short lifetime, falling into the single-digit microsecond regime.
The long emission wavelength is compatible with the UV-Vis absorption spectrum showing its lowest absorption band
around 970 nm with = 6 M-1 cm-1, and therefore seems in line with a 2E-like emission of [Cr(dpc)2]+. The uncommon
emission spectral bandwidth could have its origin in the energetic proximity of the 2LMCT state (absorption maximum
at 690 nm, but extending to nearly 900 nm) and consequent admixture of LMCT character to the emissive excited
state. It seems plausible that this contributes to the width of the emission band in Fig. 4b, because the LMCT character
implies distortions along additional nuclear coordinates.
Similarly, it seems plausible that the comparatively short luminescence lifetime of [Cr(dpc)2]+ is related to LMCT
admixture to the 2E-like emission, introducing more parity-allowed character to the resulting electronic transition and
thereby enhancing the radiative decay rate. The determination of luminescence quantum yields on frozen solutions at
77 K are technically very demanding and were not performed in the current study, hence we cannot exclude that
nonradiative relaxation contributes substantially to the emission decay even at cryogenic temperature.
No luminescence was detectable at room temperature, using experimental conditions under which we were able to
detect the weak luminescence emitted by [Cr(tpy)2]3+. This indicates that the luminescence quantum yield of
[Cr(dpc)2]+ under these conditions is below 0.00089% (Figure 1c). This could be related to the possibility that the
emission transition is not a pure spin-flip, but contains some LMCT character that entails more significant excited-
state distortions than in common CrIII polypyridines. Furthermore, the energy gap of ca. 9400 cm-1 between the
emissive excited state and the electronic ground state in [Cr(dpc)2]+ merely corresponds to approximately 3 quanta of
C-H stretching vibrations (with an approximate frequency of ca. 3000 cm-1). Consequently, electronic-vibrational
8
coupling to such high-frequency modes could readily entail efficient nonradiative relaxation, even in a scenario in
which overall excited-state distortion is relatively modest. In [Cr(ddpd)2]3+, the aromatic C-H bonds of the pyridine
units contributed most to the nonradiative excited-state decay,[8] and it seems plausible that this is also the case for
[Cr(dpc)2]+.
2.4 Ligand field parameters
The optical spectroscopic properties of Cr3+ doped inorganic materials and molecular complexes of CrIII are
traditionally analyzed in the framework of ligand field theory. The two key figures of merit are the ligand field
parameter 10 Dq and the Racah B parameter, which are measures for the magnitude of the energetic splitting between
metal-based t2g- and eg-orbitals and for metal-ligand bond covalence. Despite the fact that the symmetry of [Cr(dpc)2]+
is lower than octahedral and even though very limited information concerning the energies of MC states is available
for this compound, we consider a brief analysis in terms of ligand field theory useful, particularly because this will
allow comparison to previously investigated chromium(III) compounds. As noted above, most MC states are masked
by intense charge transfer transitions in the UV-Vis absorption spectrum of [Cr(dpc)2]+, but the 4A2 4T2 transition is
calculated to occur at 521 nm, hence 10 Dq is estimated to roughly 19200 cm-1 (equation S1). Since the 2E 4T2
emission peaks at 1067 nm, we approximate the energy of the 2E state as 9400 cm-1. Lacking further experimental
information about MC state energies in [Cr(dpc)2]+, we assume that the relationship C = 4∙B is applicable, which
represents an approximation made by many textbooks.[36] C is an additional electron-electron repulsion parameter
required to calculate the energy of the 2E state (equation S2), and using the above-mentioned relationship, a value of
470 cm-1 is obtained for the Racah B parameter. For the previously investigated [Cr(ddpd)2]3+ and [Cr(dqp)3]3+
compounds B-values of 760 cm-1 and 660 cm-1 have been reported (Table 1),[5, 9b] falling into the typical range of
Racah B parameters of Cr3+ doped oxides, fluorides, and chlorides (600 – 750 cm-1).[37]
Table 1. Ligand field parameters for selected molecular CrIII complexes and Cr3+ doped inorganic materials.a
compound 10 Dq / cm-1 B / cm-1
[Cr(ddpd)2]3+ b 22900 760
[Cr(dqp)3]3+ c 24925 660
[Cr(phen)3]3+ d 22075 780
[Cr(dpc)2]+ e 19200 470
Cr3+:-Al2O3 (ruby) f 18000 650
Cr3+:Y3Al5O12 f 16400 650
Cr3+:LiCaAlF6 f 16075 750
Cr3+:Cs2NaScCl6 g 12800 600
Cr3+:Cs2NaScYCl6 h 12800 600 a 10 Dq-values rounded to increments of 25 cm-1, B-values rounded to increments of 10 cm-1. b From ref.[5]; c from
ref.[9b]; d from ref.[38]; e this work; f from ref. [37]; g from ref.[39]; h from ref.[40].
9
Given the various approximations and experimental limitations outlined above, our own estimate for B is undoubtedly
associated with considerable uncertainty, yet it seems clear that the value of 470 cm-1 stands out. Even if we assume a
relationship of C = 3.2∙B (as was the case for [Cr(ddpd)2]3+),[5] we obtain B = 550 cm-1, which remains significantly
lower than all other Racah B parameter summarized in Table 1. It follows that the nephelauxetic parameter , which
corresponds to the ratio of B-values in a given complex and in the corresponding free ion,[12] is in the range of 0.5 to
0.6 for [Cr(dpc)2]+ (the B-value for the free Cr3+ ion is 918 cm-1,[11] see above). Within the framework of the
simplifications made for this analysis, notably the assumption of octahedral symmetry, this implies that the average
metal-ligand bond in [Cr(dpc)2]+ has unusually strong covalent character.[41]
3. Conclusions
Previously reported spin-flip emissions of chromium(III) were typically in the range between 727 and 778 nm, but the
NIR-II luminescence measured for [Cr(dpc)2]+ at 1067 nm is unprecedented to the best of our knowledge. This strong
red-shift seems to be the consequence of unusually strong metal-ligand bond covalence, which weakens the mutual
repulsion between d-electrons in the emissive excited state, thereby lowering its energy such that NIR-II luminescence
results. An energetically low-lying 2LMCT excited state furthermore influences the luminescence of [Cr(dpc)2]+,
manifesting in an overall excited-state distortion that is more substantial than in previously explored compounds and
leading to a comparatively broad emission band shape. As a further consequence of this LMCT admixture and the
lowered 2E energy, nonradiative relaxation from the emissive excited state is more efficient than in previously
investigated CrIII polypyridines.
The combination of a -donating amido unit flanked by two -accepting pyridine moieties in a bite-angle optimized,
six-membered terdentate chelate ligand enables the coordination of CrIII in a manner that -electron density can shift
from the ligands to the metal in axial direction, whereas in the equatorial plane -electron density flows from the
metal towards the ligands. These combined push- and pull-interactions can act strongly on the spectroscopically
relevant d-electrons of CrIII, and this seems to be the key to inducing a strong nephelauxetic effect and the ensuing
highly uncommon photophysical properties. Thus, our study unravels a new design principle for luminescent CrIII
compounds; whilst prior studies have focused on maximizing ligand field strength and on optimizing ligand bite
angles, our work demonstrates that increasing the metal-ligand bond covalence through combined -donor and -
acceptor interactions allows emission color tuning and can lead to NIR-II luminescence. Moreover, the inert and chiral
nature of the [Cr(dpc)2]+ chromophore open perspectives for the induction of circularly polarized emission in the NIR-
II domain while using an abundant 3d-metal.
These insights complement recent ground-breaking discoveries in the photophysics and the photochemistry of
complexes with other first-row transition metals, including V(II/III),[23, 42] Mn(IV),[43] Fe(II),[25] Fe(III),[44] Co(III),[45]
Ni(II),[46] and Cu(I).[22c, 47] It seems that much fundamental work is yet needed to fully elucidate the potential of 3d-
metals for applications in luminophores, light harvesting, sensing, photocatalysis and beyond.
10
Acknowledgments
This work was supported by the Swiss National Science Foundation through grant numbers 200021_178760 and
200020_178758. B. P. acknowledges a doctoral fellowship by the National Research Fund of Luxembourg.
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Keywords: luminescence, photophysics, chromium, UV-Vis spectroscopy, chelates